University of Ljubljana, Faculty of Electrical Engineering, Tržaška 25, 1000 Ljubljana, Slovenia.
University of Ljubljana, Faculty of Electrical Engineering, Tržaška 25, 1000 Ljubljana, Slovenia.
Bioelectrochemistry. 2021 Aug;140:107803. doi: 10.1016/j.bioelechem.2021.107803. Epub 2021 Mar 22.
High-frequency bipolar pulses (HF-BP) have been demonstrated to be efficient for membrane permeabilization and irreversible electroporation. Since membrane permeabilization has been achieved using HF-BP pulses we hypothesized that with these pulses we can also achieve successful gene electrotransfer (GET). Three variations of bursts of 2 µs bipolar pulses with 2 µs interphase delay were applied in HF-BP protocols. We compared transfection efficiency of monopolar micro and millisecond pulses and HF-BP protocols at various plasmid DNA (pDNA) concentrations on CHO - K1 cells. GET efficiency increased with increasing pDNA concentration. Overall GET obtained by HF-BP pulse protocols was comparable to overall GET obtained by longer monopolar pulse protocols. Our results, however, suggest that although we were able to achieve similar percent of transfected cells, the number of pDNA copies that were successfully transferred into cells seemed to be higher when longer monopolar pulses were used. Interestingly, we did not observe any direct correlation between fluorescence intensity of pDNA aggregates formed on cell membrane and transfection efficiency. The results of our study confirmed that we can achieve successful GET with bipolar microsecond i. e. HF-BP pulses, although at the expense of higher pDNA concentrations.
高频双相脉冲(HF-BP)已被证明在细胞膜通透性和不可逆电穿孔方面非常有效。由于已经使用 HF-BP 脉冲实现了细胞膜通透性,我们假设我们也可以使用这些脉冲实现成功的基因电转移(GET)。在 HF-BP 方案中,应用了三种 2µs 双相脉冲的爆发,具有 2µs 的相间延迟。我们比较了单极微秒和毫秒脉冲以及不同质粒 DNA(pDNA)浓度下的 HF-BP 方案在 CHO-K1 细胞上的转染效率。GET 效率随 pDNA 浓度的增加而增加。总体而言,HF-BP 脉冲方案获得的 GET 与更长的单极脉冲方案获得的 GET 相当。然而,我们的结果表明,尽管我们能够达到类似的转染细胞百分比,但当使用更长的单极脉冲时,成功转移到细胞中的 pDNA 拷贝数似乎更高。有趣的是,我们没有观察到形成在细胞膜上的 pDNA 聚集体的荧光强度与转染效率之间存在任何直接相关性。我们的研究结果证实,我们可以使用双相微秒即 HF-BP 脉冲成功实现 GET,尽管代价是更高的 pDNA 浓度。
